Melt Extract Stainless Steel Fiber for Construction Companies UAE High Quality Steel Fiber CNBM

Melt Extract Stainless Steel Fiber for Construction Companies UAE High Quality Steel Fiber CNBM

Ref Price:

Loading Port:: Tianjin

Payment Terms:: TT OR LC

Min Order Qty:: 1 m.t.

Supply Capability:: 600 m.t./month

Inquire Now

Add to My Favorites

OKorder Service Pledge

Quality Product, Order Online Tracking, Timely Delivery

OKorder Financial Service

Credit Rating, Credit Services, Credit Purchasing

Quick Details

Place of Origin: Tianjin, China (Mainland)
Model Number: 0.5
Material: Steel
Production Process: Cold drawn
Fiber Lengh: 30
Type: 1
Compressive Strength: >1200MPa
Aspect ratio: 60
Standard: ASTM A820M-11
Section Shape: Circular
Application: Concrete Reinforcement
Product Application: Industrial Floor

Packaging & Delivery

Packaging Details:	20 kg/Bag,50 bags/Pallet or 1,000kg/ Bulk Bag
Delivery Detail:	1 Month

Product Description

Diameter	0.5 mm (0.197 in)
Length	30 mm (11.811 in)
Aspect Ratio	60
Tensile strength	1200 MPa
Type	Cold drawn Steel Fiber
End	Hooked-end Steel Fiber
Glued/Loose	Glued Steel Fiber
Bending Angle	45°(min.30°)
Usage & Performance	Floor:Trafficked areas and Industrial floors
	Shotcrete :Slope stabilization and Final lining
	Precast concrete:Pipe and Railway sleepers
Packing	Standard Export Pallet Packing	Bag Packing	20 kg/Bag,50 bags/Pallet
		Bulk Packing	1,000kg/ Bulk Bag
Loading Quantity	20’GP	20-25 Tonne/Tonnes
	40’GP	25-27 Tonne/Tonnes
	40’HQ	25-27 Tonne/Tonnes
MOQ	1 kg for trial order
Supply Ability	10,000 Tonne/Tonnes per Year
Payment Terms	T/T or L/C at sight
Delivery Time	Within 15 days after receiving deposit or original L/C at sight
Certification	ISO9001:2000, CE,

Product	Diameter	Length mm/in	Aspect Ratio	Type	Packing
G-6030	0.5 mm (0.197 in)	30 mm (11.811 in)	60	Glued	20 kg/Bag, or 1,000kg/ Bulk Bag
G-6535	0.55 mm (0.217 in)	35 mm (13.780 in)	65	Glued	20 kg/Bag, or 1,000kg/ Bulk Bag
G-6035	0.6 mm (0.236 in)	35 mm (13.780 in)	60	Glued	20 kg/Bag, or 1,000kg/ Bulk Bag
G-8060	0.75 mm (0.295 in)	60 mm (23.622 in)	80	Glued	20 kg/Bag, 50 bags/Pallet
G-6060	0.9 mm (0.354 in)	60 mm (23.622 in)	60	Glued	20 kg/Bag, 50 bags/Pallet
G-6030	0.5 mm (0.197 in)	30 mm (11.811 in)	60	Loose	20 kg/Bag, or 1,000kg/ Bulk Bag
G-6535	0.55 mm (0.217 in)	35 mm (13.780 in)	65	Loose	20 kg/Bag, or 1,000kg/ Bulk Bag
G-6035	0.6 mm (0.236 in)	35 mm (13.780 in)	60	Loose	20 kg/Bag, or 1,000kg/ Bulk Bag
G-8060	0.75 mm (0.295 in)	60 mm (23.622 in)	80	Loose	20 kg/Bag, 50 bags/Pallet
G-6060	0.9 mm (0.354 in)	60 mm (23.622 in)	60	Loose	20 kg/Bag, 50 bags/Pallet

Q: Can melt extract stainless steel fiber be used in architectural concrete finishes?: Yes, melt extract stainless steel fiber can be used in architectural concrete finishes. It is commonly used to improve the durability, strength, and crack resistance of concrete, making it suitable for various architectural applications.

Q: How does the addition of melt extract stainless steel fiber affect the rheology of concrete?: The addition of melt extract stainless steel fiber significantly affects the rheology of concrete by improving its overall performance and durability. One of the main effects of incorporating stainless steel fibers is the enhancement of concrete's tensile and flexural strength. The fibers act as reinforcement within the concrete matrix, effectively bridging cracks and increasing its resistance to cracking and fatigue. This results in a more ductile and robust material that can withstand higher loads and stresses without failure. Moreover, the addition of stainless steel fibers also improves the rheological properties of concrete. These fibers, being extremely fine and flexible, enhance the workability of the mix by reducing the viscosity and improving the flowability. This makes the concrete easier to pump, place, and compact, ultimately leading to better consolidation and higher quality finishes. Additionally, the presence of stainless steel fibers in concrete can modify its setting and hardening characteristics. The fibers act as nucleation sites for hydration products, accelerating the cement hydration process and promoting early strength development. This can be particularly beneficial in construction projects where fast setting times are required or in cold weather conditions where concrete may be prone to freezing. Furthermore, the stainless steel fibers also contribute to the overall durability of concrete. They provide a physical barrier against corrosion by reinforcing the concrete and preventing the ingress of moisture and aggressive chemicals, thus increasing the lifespan of the structure. This is especially crucial in harsh environments or in structures exposed to chemical attacks, such as wastewater treatment plants or marine structures. In conclusion, the addition of melt extract stainless steel fibers brings numerous benefits to the rheology of concrete. It improves its strength, workability, and durability, making it a reliable and high-performance construction material.

Q: Are there any specific curing requirements for concrete with melt extract stainless steel fiber?: Concrete with melt extract stainless steel fiber has specific curing requirements that need to be addressed. It is important to understand that the inclusion of stainless steel fibers in concrete can greatly improve its mechanical properties, such as tensile strength and resistance to cracking. However, these fibers can also impact the curing process, necessitating certain considerations. One crucial requirement is the need for adequate moisture during the curing process. It is essential to keep concrete with stainless steel fibers moist to prevent premature drying, which can result in shrinkage and cracking. To retain moisture and ensure proper hydration, moist curing methods like using wet burlap or plastic sheets can be employed. Temperature control is another critical aspect of the curing period. High temperatures can accelerate the hydration process, leading to increased shrinkage and potential cracking. Conversely, low temperatures can hinder curing and result in reduced strength development. Therefore, maintaining a moderate and consistent temperature is vital for the proper curing of concrete with stainless steel fibers. Moreover, it is advisable to prolong the duration of the curing period for concrete with stainless steel fibers. The presence of fibers can impede water movement within the concrete matrix, slowing down hydration. By extending the curing time, the concrete has more opportunity to develop the desired strength and durability. Lastly, it is crucial to adhere to the manufacturer's recommendations regarding curing requirements for concrete with melt extract stainless steel fibers. Different fiber types and manufacturers may have specific guidelines and recommendations for curing, which should be followed to ensure optimal performance of the concrete. To summarize, the curing requirements for concrete with melt extract stainless steel fibers involve maintaining moisture, controlling temperature, extending the curing period, and following manufacturer guidelines. By fulfilling these requirements, the concrete can achieve its desired strength and durability while benefiting from the enhanced properties provided by the stainless steel fibers.

Q: What is the typical fiber length of melt extract stainless steel fiber?: The typical fiber length of melt extract stainless steel fiber is usually between 0.5 to 2 inches.

Q: What is the recommended fiber dosage for melt extract stainless steel fiber in shotcrete?: The recommended fiber dosage for melt extract stainless steel fiber in shotcrete typically ranges from 25 to 35 kg/m3. However, it is important to note that the specific dosage may vary depending on factors such as the desired strength, durability, and overall performance requirements of the shotcrete application. It is recommended to consult with the manufacturer or a structural engineer to determine the optimal fiber dosage for the specific project.

Q: How does the addition of melt extract stainless steel fiber impact the shrinkage of concrete?: Melt extract stainless steel fiber has a substantial impact on the shrinkage of concrete. Its addition enhances the strength, durability, and crack resistance of the concrete. When incorporated into the mix, these fibers reinforce the concrete and reduce its overall shrinkage. Concrete naturally shrinks as it dries and loses moisture. This shrinkage can cause cracks, compromising the structure's integrity and lifespan. However, the addition of melt extract stainless steel fibers minimizes shrinkage and significantly reduces the likelihood of cracks. The stainless steel fibers create a three-dimensional network within the concrete, resisting the tensile forces that occur during shrinkage. This prevents cracks from forming and improves the material's performance by distributing stress throughout. Moreover, melt extract stainless steel fibers improve the behavior of concrete after cracking. If cracks do appear, the fibers act as reinforcement, bridging across the cracks and preventing further propagation. This strengthens the concrete's structure. In conclusion, incorporating melt extract stainless steel fibers into concrete significantly reduces shrinkage and enhances crack resistance. This not only improves the concrete's durability and lifespan, but also ensures its ability to withstand external forces and environmental conditions.

Q: Can melt extract stainless steel fiber be used in self-compacting concrete applications?: Indeed, self-compacting concrete (SCC) applications can utilize melt extract stainless steel fiber. SCC is renowned for its capacity to effortlessly flow and fill intricate and congested reinforcement areas without necessitating external vibration. The inclusion of stainless steel fibers can bolster the mechanical attributes of SCC, encompassing flexural and impact strength, crack resistance, and durability. Melt extract stainless steel fibers possess commendable tensile strength and corrosion resistance, rendering them appropriate for SCC implementation. These fibers are typically generated by melting stainless steel and subsequently swiftly extracting it into fine filaments. Subsequently, these filaments are aggregated to construct the stainless steel fibers. By incorporating melt extract stainless steel fibers into SCC, the concrete's ductility and toughness can be heightened. This is particularly advantageous in scenarios where elevated structural performance is imperative, such as in bridge decks, tunnels, and high-rise structures. These fibers serve to impede crack propagation and augment the overall durability of the concrete. Furthermore, melt extract stainless steel fibers can also enhance the fire resistance of SCC. Stainless steel boasts a high melting point and retains its strength even at elevated temperatures, thus rendering it an optimal reinforcement material in fire-prone regions. Nevertheless, it is crucial to note that the dosage and distribution of stainless steel fibers should be meticulously considered to guarantee optimal performance. The fiber length, aspect ratio, and volume fraction ought to be selected based on the specific requirements of the SCC application. To conclude, melt extract stainless steel fiber can certainly be employed in self-compacting concrete applications. Their integration can amplify the mechanical properties, durability, and fire resistance of SCC, thereby making it a fitting selection for a diverse array of construction projects.

Q: Are there any limitations or drawbacks of using melt extract stainless steel fiber in concrete?: There are indeed limitations and disadvantages associated with the use of melt extract stainless steel fiber in concrete. To begin with, one limitation is the expensive nature of melt extract stainless steel fibers. Compared to other fiber types like polypropylene or glass fibers, stainless steel fibers can be considerably pricier. This can significantly raise the overall cost of using stainless steel fibers in concrete, which may deter construction projects with budget constraints. Additionally, the inclusion of stainless steel fibers can increase the viscosity of the concrete mixture, making it more challenging to work with during placement and finishing. This can result in longer construction times and higher labor costs. Moreover, stainless steel fibers can give rise to corrosion problems in certain environments. While stainless steel is generally resistant to corrosion, it can still corrode in aggressive environments such as those rich in chloride or acidic substances. Consequently, this can diminish the durability and performance of the concrete over time. Another drawback of using stainless steel fibers is the potential formation of fiber balls. During the mixing process, the fibers can clump together and form these fiber balls. This uneven distribution of fibers within the concrete can decrease reinforcement efficiency and potentially compromise the structural integrity of the concrete. Furthermore, the use of stainless steel fibers can affect the workability of the concrete mixture. The fibers can cause segregation, resulting in an irregular distribution of aggregate and cement paste. Ultimately, this can lead to a decrease in the overall strength and durability of the concrete. Lastly, the addition of stainless steel fibers can also impact the appearance of the concrete surface. The fibers may be visible on the surface, which may be undesirable in certain architectural or decorative applications. In conclusion, while melt extract stainless steel fibers offer improved mechanical properties and durability to concrete, they also come with limitations and drawbacks such as high cost, increased viscosity, potential corrosion, fiber balling, reduced workability, and impact on the concrete surface appearance. These factors should be carefully considered when deciding whether to use melt extract stainless steel fibers in concrete.

Q: What is the difference between melt extract stainless steel fiber and other types of steel fibers?: Melt extracted stainless steel fiber, also referred to as melt extract steel fiber, is produced by melting stainless steel and then swiftly drawing it into fine fibers. This manufacturing process yields fibers with distinct properties and characteristics compared to alternative steel fibers. An important distinction of melt extract stainless steel fiber from other varieties is its improved resistance to corrosion. Stainless steel is renowned for its capacity to withstand corrosion and oxidation, rendering melt extract stainless steel fibers highly impervious to rust and degradation over time. Consequently, they are suitable for use in environments prone to exposure to moisture, chemicals, or other corrosive substances. Another distinction lies in the heightened tensile strength of melt extract stainless steel fibers. The expedited extraction process aligns the steel molecules, resulting in fibers that are more robust and durable than their counterparts. This augmented tensile strength makes melt extract stainless steel fibers optimal for reinforcing concrete or other materials that necessitate high strength and durability. Additionally, melt extract stainless steel fibers exhibit exceptional thermal and electrical conductivity. This attribute makes them suitable for applications requiring efficient heat or electricity transfer. For instance, they can be employed in heating elements, electromagnetic shielding, or as conductive reinforcement in composites. Lastly, melt extract stainless steel fibers possess a smoother surface compared to other steel fibers. This smooth surface promotes improved bonding with the surrounding matrix, such as concrete or resin, leading to enhanced load transfer and overall performance. Furthermore, the smoothness reduces the likelihood of fiber pull-out or breakage, further enhancing their effectiveness as reinforcement materials. In conclusion, melt extract stainless steel fibers distinguish themselves from alternative steel fibers due to their enhanced corrosion resistance, increased tensile strength, exceptional thermal and electrical conductivity, and smoother surface. These distinctive properties render them a preferred choice for various applications requiring high-performance reinforcement materials.

Q: How does melt extract stainless steel fiber improve the resistance of concrete to carbonation?: Melt extract stainless steel fiber improves the resistance of concrete to carbonation by enhancing the durability and longevity of the concrete structure. The stainless steel fibers act as reinforcement within the concrete matrix, reducing the formation of cracks and improving its overall resistance to carbonation. This reinforcement helps to prevent the ingress of carbon dioxide into the concrete, minimizing the deterioration caused by carbonation and increasing its service life.

Send your message to us

*Email

*TEL

*Quantity

*Unit